Aldol ketone acceptors

The Robinson annulation is a two-step process that combines a Michael reaction with an intramolecular aldol reaction. It takes place between a nucleophilic donor, such as a /3-keto ester, an enamine, or a /3-diketone, and an a,/3-unsaturated ketone acceptor, such as 3-buten-2-one. The product is a substituted 2-cyclohexenone. 

Most recently, reductive aldol cyclization catalyzed by In(OAc)3 in the presence of PhSiH3 was reported.50 This catalytic system is applicable to both aldehyde and ketone acceptors. As demonstrated by the reductive cyclization of 65a and 68a, cycloaldol products are produced in good yields and excellent ry -diastereoselectivity (Scheme 48). 

Scheme 2.7 Aldol reactions with ketone acceptors [33-36].

In addition to ketones, aldehydes can also be used as aldol donors in pro-line-catalyzed reactions [144]. Barbas et al. found that treating acetaldehyde solutions tvith proline provided aldehyde 185, an aldol trimer of acetaldehyde, in 84% ee and 4% yield (Scheme 4.42, Eq. (1)) [145, 146]. As shotvn by Jorgensen et al., other simple a-unbranched aldehydes can also be used as donors in proline-catalyzed cross aldolization tvith activated non-enolizable ketone acceptors to give aldols 188 in high enantioselectivity and yield (Scheme 4.42, Eq. (2)) [147]. 

A pyruvate aldolase from Pseudomonas taetrolens catalyzes the aldol addition of pyru-vafe to indole-pyruvic acid (34), a ketone [85]. This is an interesting example of an aldolase fhaf cafalyzes an aldol addition to a ketone acceptor. A variant of this aldolase was used in fhe stereoselective synfhesis of a precursor (35) of monatin (36), whose 2R,4R stereoisomer is 2700-fold sweeter fhan sucrose (Scheme 10.3) [86]. 

Gong group designed chiral primary amine-amide type catalyst for the aldoliza-tion of hydroxyacetone [24] with excellent iyn-aldol selectivity (up to >20 1 dr.) and stereoselectivity (up to 98% ee) (Scheme 5.12). Recently, Zhao and Da have further explored this type of primary amine catalysts [25]. Feng developed bispidine-derived chiral primary amine catalyst 45 for the aldolization of activated ketone acceptors with excellent enantioselectivity (Scheme 5.12) [26]. 

Since most often the selective formation of just one stereoisomer is desired, it is of great importance to develop highly selective methods. For example the second step, the aldol reaction, can be carried out in the presence of a chiral auxiliary—e.g. a chiral base—to yield a product with high enantiomeric excess. This has been demonstrated for example for the reaction of 2-methylcyclopenta-1,3-dione with methyl vinyl ketone in the presence of a chiral amine or a-amino acid. By using either enantiomer of the amino acid proline—i.e. (S)-(-)-proline or (/ )-(+)-proline—as chiral auxiliary, either enantiomer of the annulation product 7a-methyl-5,6,7,7a-tetrahydroindan-l,5-dione could be obtained with high enantiomeric excess. a-Substituted ketones, e.g. 2-methylcyclohexanone 9, usually add with the higher substituted a-carbon to the Michael acceptor ... 

The mixed Claisen condensation of two different esters is similar to the mixed aldol condensation of two different aldehydes or ketones (Section 23.5). Mixed Claisen reactions are successful only when one of the two ester components has no a hydrogens and thus can t form an enolate ion. For example, ethyl benzoate and ethyl formate can t form enolate ions and thus can t serve as donors. They can, however, act as the electrophilic acceptor components in reactions with other ester anions to give mixed /3-keto ester products. 

In this example, the /3-diketone 2-methyJ-l,3-cyclopentanedione is used to generate the enolate ion required for Michael reaction and an aryl-substituted a,/3-unsaturated ketone is used as the acceptor. Base-catalyzed Michael reaction between the two partners yields an intermediate triketone, which then cyclizes in an intramolecular aldol condensation to give a Robinson annulation product. Several further transformations are required to complete the synthesis of estrone. 

The aldol reaction is a carbonyl condensation that occurs between two aldehyde or ketone molecules. Aldol reactions are reversible, leading first to a /3-hydroxy aldehyde or ketone and then to an cr,/6-unsaturated product. Mixed aldol condensations between two different aldehydes or ketones generally give a mixture of all four possible products. A mixed reaction can be successful, however, if one of the two partners is an unusually good donor (ethyl aceto-acetate, for instance) or if it can act only as an acceptor (formaldehyde and benzaldehyde, for instance). Intramolecular aldol condensations of 1,4- and 1,5-diketones are also successful and provide a good way to make five-and six-inembered rings. 

Crossed aldol condensations, where both aldehydes (or other suitable carbonyl compounds) have a-H atoms, are not normally of any preparative value as a mixture of four different products can result. Crossed aldol reactions can be of synthetic utility, where one aldehyde has no a-H, however, and can thus act only as a carbanion acceptor. An example is the Claisen-Schmidt condensation of aromatic aldehydes (98) with simple aliphatic aldehydes or (usually methyl) ketones in the presence of 10% aqueous KOH (dehydration always takes place subsequent to the initial carbanion addition under these conditions) ... 

In the general context of donor/acceptor formulation, the carbonyl derivatives (especially ketones) are utilized as electron acceptors in a wide variety of reactions such as additions with Grignard reagents, alkyl metals, enolates (aldol condensation), hydroxide (Cannizzaro reaction), alkoxides (Meerwein-Pondorff-Verley reduction), thiolates, phenolates, etc. reduction to alcohols with lithium aluminum hydride, sodium borohydride, trialkyltin hydrides, etc. and cyloadditions with electron-rich olefins (Paterno-Buchi reaction), acetylenes, and dienes.46... 

Here the hapten (Scheme 2) is a 13-diketone, which incorporates structural features of both reactants - ketone donor and aldehyde acceptor (see below, Scheme 3) - in the aldol reaction of interest. In favorable cases the hapten reacts with the primary amino-group of a lysine residue in the complementary-determining region of an antibody to form a Schiffbase 5, which readily tautomerises to the more stable vinylogous amide 6. 

Furthermore, the N-alkylation of 2-aminobenzyl alcohol 114 with ketones 115 in the presence of [IrCl(cod)]2 and KOH gave quinoline derivatives 116 (Equation 10.28) [52]. The reaction may be initiated by the formation of ketimine from 114 and 115, and the ketimine thus formed is oxidized by Ir catalyst and the 114 which serves as a hydrogen acceptor giving the corresponding aldehyde, which is eventually converted into quinoline 116 through intramolecular aldol-type condensation. 

Scheme 14 Equilibria in aldol reactions with ketone and aldehyde acceptors...

Typical starting materials, catalysts, and products of the enamine-catalyzed aldol reaction are summarized in Scheme 17. In proline-catalyzed aldol reactions, enantioselectivities are good to excellent with selected cyclic ketones, such as cyclohexanone and 4-thianone, but generally lower with acetone. Hindered aldehyde acceptors, such as isobutyraldehyde and pivalaldehyde, afford high enantioselectivities even with acetone. In general, the reactions are anti selective, but there are aheady a number of examples of syn selective enamine aldol processes [200, 201] (Schemes 17 and 18, see below). However, syn selective aldol reactions are still rare, especially with cychc ketones. 

Ketones cannot generally be used as acceptors, at least not directly, due to unfavorable equilibrium between the aldol product and the starting ketones. However, highly reactive ketones [87, 88], such as isatin 2 [95] (Fig. 3) and a-keto phosphonates (e.g. 112) [110] can readily be used as acceptors. 

In enamine-catalyzed aldol reaction, the donor aldehyde or ketone first forms an enamine and then reacts with another aldehyde to form the aldol product. If imines instead of aldehydes are used as acceptors, the end result is the formation of a... 

The first asymmetric enamine-catalyzed Mannich reactions were described by List in 2000 [208]. Paralleling the development of the enamine-catalyzed aldol reactions, the first asymmetric Mannich reactions were catalyzed by proline, and a range of cyclic and acyclic aliphatic ketones were used as donors (Schemes 24 and 25). In contrast to the aldol reaction, however, most Mannich reactions are syn selective. This is presumably due to the larger size of the imine acceptor, forcing the imine and the enamine to approach each other in a different manner than is possible with aldehyde acceptors (Scheme 23). 

Aldolases are part of a large group of enzymes called lyases and are present in all organisms. They usually catalyze the reversible stereo-specific aldol addition of a donor ketone to an acceptor aldehyde. Mechanistically, two classes of aldolases can be recognized [4] (i) type I aldolases form a Schiff-base intermediate between the donor substrate and a highly conserved lysine residue in the active site of the enzyme, and (ii) type II aldolases are dependent of a metal cation as cofactor, mainly Zn, which acts as a Lewis acid in the activation of the donor substrate (Scheme 4.1). 

The stereochemistry of the aldol reaction is highly predictable since it is generally controlled by the enzyme and does not depend on the structure or stereochemistry of the substrates. Aldolases generally show a very strict specificity for the donor substrate (the ketone), but tolerate a broad range of acceptor substrates (the aldehyde). Thus, they can be functionally classified on the base of the donor substrate accepted by the enzyme. 

In this case, the 2-aminobenzyl alcohol is oxidized to 2-aminobenz-aldehyde, which undergoes an aldol condensation with the ketone to give an 0, /3-unsaturated ketone. This is followed by cyclodehydratisation to form quinoline. An excess of ketone is necessary to act as a sacrificial hydrogen acceptor. 

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